System and method of photoionization of fullerene and derivative clusters for high thrust-density ion thrusters

ABSTRACT

The present invention is for a system and a method of VUV photoionization of fullerene and derivative clusters followed by their thermal effusion for a practical energy-efficient and economically-viable high thrust density ion thruster. By taking advantage of the state-of-the-art high intensity VUV photon sources, present invention is able to provide much softer ionization with minimal internal energy deposition than the ionization in the electron impact or charge exchange type ionization in plasma environment used in conventional ion thrusters. Because the invention eliminates the need of additional gas for forming discharge plasma, it permits simpler and lighter structures than the conventional fullerene thrusters with significantly enhanced propellant-usage efficiencies, thrust to power ratios, and thrust to weight ratios. Because the present invention employs softer VUV photoionization, it permits the usage of heavier and more complex fullerene derivatives, nanotubes, and nanotube derivatives than fullerene clusters for fuels without significantly fragmenting them.

PRIORITY NOTICE

The present application claims priority, under 35 USC §199(e) and under 35 USC §120, to the U.S. Provisional Patent with Application Ser. No. 61/409,963 filed on Nov. 4, 2010, the disclosure of which is incorporated herein by reference in its entirety.

GOVERNMENT INTEREST

This invention was made with Government support under Contract No. HDTRA1-10-C-0088 awarded by the Defense Threat Reduction Agency. The Government has certain rights in the invention.

COPYRIGHT & TRADEMARK NOTICE

A portion of the disclosure of this patent document contains material, which is subject to copyright protection. The owner has no objection to the facsimile reproduction by any one of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyrights whatsoever.

Certain marks referenced herein may be common law or registered trademarks of third parties affiliated or unaffiliated with the applicant or the assignee. Use of these marks is by way of example and shall not be construed as descriptive or to limit the scope of this invention to material associated only with such marks.

REFERENCES CITED US Patent Documents

-   U.S. Pat. No. 5,239,820 August 1993 Leifer et al.

Other Publications

-   Anderson et al., “Fullerene Propellant Research for Electric     Propulsion,” AIAA 96-3211, 32nd AIAA/ASME/SAE/ASEE Joint Propulsion     Conference and Exhibit, Lake Buena Vista, Fla., 1996. -   Leifer, S. D., “Characterization of Fullerenes for Electrostatic     Propulsion Applications,” Ph.D. Dissertation, California Institute     of Technology, 1995. -   Leifer et al., “Thermal Decomposition of a Fullerene Mix,” Physical     Review B 51, 9973-9978, 1995. -   Leifer et al., “Developments in Fullerene Ion Propulsion Research,”     AIAA/SAE/ASEE 30″ h Joint Propulsion Conference, Indianapolis, Ind.,     1994. -   Leifer, et al., “Effect of the Thermal Stability and Reactivity of     Fullerenes on Ion Engine Propellant Applications,” 25th AIAA     Plasmadynamics and Lasers Conference, Colorado Springs, Co., 1994. -   Anderson, et al., “Design and Testing of a Fullerene RF Ion Engine,”     AIAA-95-2664, 31st Joint Propulsion Conference, San Diego, July     1995. -   Anderson et al., “Fullerene Propellant Research for Electric     Propulsion,” AIAA 96-3211, 32nd Joint Propulsion Conference, Lake     Buena Vista, July 1996. -   Takegahara et al., “C60 Molecule as a Propellant for Electric     Propulsion,” IEPC-93-032, 23rd International Electric Propulsion     Conference, September 1993. -   Nakayama et al., “Fundamental Experiments of C60 Application to Ion     Thruster,” IEPC-95-88, 24th International Electric Propulsion     Conference, September 1995. -   Takegahara et al., “C60 Feasibility Study on Application to Ion     Thruster Preliminary Experiments Using Electron Bombardment     Thruster,” AIAA 95-2665, 31^(st) Joint Propulsion Conference, San     Diego, July 1995. -   Nakayama et al. “Study on C60 Application to Ion Thruster-Evaluation     of Ion Production,” 32nd Joint Propulsion Conference, Lake Buena     Vista July 1996. -   Tones, “Prediction of the Performance of an Ion Thruster Using     Buckminsterfullerene as the Propellant,” Master of Science Thesis,     MIT, February 1993. -   Hruby, et al., “A High Thrust Density, C60 Cluster, loon Thruster,”     AIAA 94-2466, 25th Plasmadynamics and Lasers Conference, Colorado     Springs, June 1994. -   Hruby, et al., “Fullerene Fueled Electrostatic Thrusters—Feasibility     and Initial Experiments,” AIAA 94-3240, 30th Joint Propulsion     Conference, Indianapolis, June 1994. -   Hruby, et al., “A High Thrust Density, C₆₀ Cluster Ion, Thruster,”     AFOSR Final Report No. 49620-94-C-0006, September 1996.

TECHNICAL FIELD OF THE INVENTION

The present invention relates in general to ion thrusters for space propulsion.

BACKGROUND OF THE INVENTION

Ion thrusters or engines have played vital role in space propulsion for wide ranges of applications, such as low thrust precision attitude control, orbit transfer and interplanetary flights. One of crucial parameters of ion thrusters, which determine its applicability to specific missions, is the thrust density, the ratio of the thrust to the area of the exit nozzle/electrode. The high thrust density correlates with a smaller accelerator grid area that is essential in minimizing the construction, operation and lifting costs of the ion thrusters. Although the power to thrust conversion efficiency and I_(sp) of ion thrusters can be much higher than conventional chemical thrusters, the ion thrusters currently are not used for missions requiring large thrusts in the order of multi megawatts, because their construction and lifting costs are prohibitive. Therefore, the methods of increasing thrust density of ion thrusters can significantly broaden their application scopes have been extensively sought for.

The operation of the ion thruster relies on acceleration of ions. Thus, the space-charge limitation of the ion acceleration process limits the thrust density. Currently, most of ion thrusters use atomic species, such as Xe or Hg making the ion thruster practical for only a limited range of missions. Extensive research efforts have attempted to increase thrust density to levels that would lead to an attractive ion thruster with wider applicability with the use of heavier ion species than Xe or Hg without success. The method of increasing thruster density can be guided by a physical theory by Child-Longmuir law, and according to this law, the thrust density, T_(a), of an ion thruster can be given by:

T_(a)∝m_(i) ²I_(sp) ⁴,  (1)

where I_(sp) is the specific impulse and m_(i) is the ion mass of the propellant. For a specific mission with a fixed I_(sp), the higher the ion mass is, the higher is the thruster density. Because the thrust density is proportional to square of the ion mass, even small change in ion mass can increase the thrust density significantly. For example, the atomic mass of the most popular propellant Xe is 131, and any fuels with atomic or molecular mass greater than 131 would increase the thrust density over the current limit.

Molecular or cluster ions can potentially increase ion mass significantly, however, with highly increased probability of fragmentation, which negates the effect of increased ion mass on thrust density. Therefore, the usage of molecular or cluster ions for ion thrusters has not been successful until now. Fullerene clusters, such as C₆₀, have much larger masses than Xe, yet under favorable thermodynamic conditions, they behave like atoms in terms of resisting fragmentation. In addition to their larger mass than that atomic species, fullerene clusters have lower ionization potentials, thus require lesser energy for ionization than atomic species. Fullerene clusters can be sublimated at relatively low temperatures without fragmentation, and their vapors behave like atomic vapors. Therefore, the usage of C₆₀ for propellant for ion thrusters has been extensively investigated by researchers over two decades.

For example, C₆₀ clusters, cardinal clusters among fullerenes, have a mass of 720. If thrust operation conditions are kept the same, the thrust density of C₆₀ ions would be greater than Xe ions by a factor of (720/131)²˜30 according to Eq. 1. For example, a high thrust mission with a thruster beam power of 10 MW and I_(sp)-5,000 with Xe as propellant would need a grid area of 18 m², which is too large for economically viable construction and lift into space. If a similar ion thruster can be operated with C₆₀ fuel, the required grid area decreases to 0.60 m², which is economically viable for a wide range of space missions. The heavier fullerenes, such as C₇₂ or C₈₄ would have better size-reduction effects. The chemistry of fullerenes has recently produced extensive classes of fullerene derivatives, fullerene nanotubes, and fullerene nanotube derivatives. Successful usages of these large stable clusters will further increase the thruster density. Therefore, fullerene-family fuels may open new doors for electrostatic propulsion, if they can be successfully used in ion thrusters.

Extensive research and development efforts for fullerene ion thrusters have at best produced engines with undesirably low fuel usage efficiency due to serious propellant deposition and other problems resulting from premature fragmentation before full electrostatic acceleration. Previous state-of-the-art fullerene ion thrusters have used traditional ionization methods including DC and RF discharge plasmas. An example C₆₀-based ion thruster system is described in U.S. Pat. No. 5,239,820, entitled “Electric Propulsion Using C₆₀ Molecules,” issued Aug. 31, 1993, to Leifer et al., the disclosure of which is incorporated herein by reference. The prior usage of such ion thruster structures and operation methods with cathodes and hot filaments in DC or RF discharge chambers has not successful in realizing efficient and practical fullerene ion thrusters. A number of publications similar to the above mentioned C₆₀ ion thruster system reported a failure of obtaining sufficiently high efficiency of fullerenes for rendering C₆₀ ion thruster practically and economically viable, which have been incorporated herein by reference. Other methods include the usage of charge exchange of fullerene with rare gas ions generated in discharge chambers in a modified configuration of Hall thrusters. An example such ion thruster system is described in Hruby, et al., “A High Thrust Density, C₆₀ Cluster Ion, Thruster,” AFOSR Final Report No. 49620-94-C-0006, September 1996, the publication of which is incorporated herein by reference. Such approach also resulted in similar inefficiency of fullerene usage to the above mentioned references.

None of the existing approaches so far resulted in a practical fullerene ion thruster, mainly because their ionization methods for generating fullerene cluster ions induce extensive fragmentation of fullerene clusters resulting in very low efficiency fullerene usage. Therefore, other innovative ion thruster structures and operation methods have been sought for. The present invention solves these problems in existing fullerene ion thrusters with the use of VUV photoionization followed by thermal effusion of fullerene clusters, which has negligible fragmentation during ionization process, thus promises cost effective and practical fullerene ion thrusters for a wide range of space propulsion applications.

SUMMARY OF THE INVENTION

The inventor realized that the fundamental problem in the existing fullerene ion thrusters is in the ionization process of fullerenes and transportation process of the fullerene ions ant that the problem can be avoided by using a much gentler ionization method than the ones used in previous works or inventions. The present state-of-the-art fullerene ion thrusters use either electron impact ionization or charge exchange with other rare gases in hot filament environment as used in existing methodologies. Such ionization processes can deposit large internal energy into fullerenes after ionization. The hot filament discharge environment can also rapidly destroy fullerenes. These hot fullerene ions can readily fragment in very short time during acceleration even without collision with rare gas atoms. To make the situation worse, in the traditional fullerene thrusters, transportation of fullerene ions is performed in the mixture of fullerene and rare gas atom vapors at relatively high pressure resulting in further extensive collisional fragmentation.

The salient feature of the present invention lies in the usage of VUV photoionization of molecular beams of fullerene clusters generated by molecular beam sources, including but not limited to Knudsen cells. The photoionization with controlled photon energy can softly ionize fullerenes without depositing extensive internal energy that can fragment fullerene ions. The photoionization cross sections above the ionization potential of fullerene are well investigated. For example, the ionization potential of C₆₀ is 7.58 eV, and its photoionization cross section at 10 eV is ˜10 ⁻¹⁶ cm², which is sufficient for efficient and soft photoionization with minimal fragmentation. The reason for this is that during photoionization at photon energy close to the photoionization threshold, the thermal energy, which induces fragmentation, imparted to fullerenes is minimal, and most of photon energy is used for expelling electrons.

The present invention can also minimize fragmentation during evaporation of fullerenes, because the present invention does not require enclosed structures for ionization process, which are required for containing DC or RF energies in prior arts. Since the present invention does not require such heavy enclosed structures for ionization, in principle, the ionization area can be arbitrarily large without increasing the overall weight of the thruster. This advantage allows to lower evaporation temperature of fullerenes sufficiently below the fragmentation threshold temperature resulting in minimal thermal fragmentation. For example, if the photoionization region has a diameter of 30 cm, the unit ionization efficiency can be achieved with fullerene densities in the order of 3×10¹⁴/cm³. Such a fullerene number density can be achieved by heating the fullerene solid to 650 C well below the thermal fragmentation temperature of 750 C by molecular beam sources including but not limited to Knudsen cells. With such configuration, almost all fullerenes can be efficiently ionized and accelerated together, thus the collisional fragmentation can be minimized as well. These advantages can not be found in prior art.

The photoionization of fullerenes require intense VUV photon sources with photon energies in excess of 10 eV, well above the photoionization threshold energy, 7.58 eV, of fullerenes. The ideal VUV photons should have high enough photon energy to have reasonably large photoionization cross sections, but low enough photon energy not to fragment fullerenes. The ideal photon energy thus is ˜10-20 eV. Such photon energy can be readily achieved by the above mentioned VUV photon source technologies. The new development in VUV photon lamps, including but not limited to, rare gas resonance lamps, rare gas excimer lamps, now provides the required high flux of VUV photons with high efficiency. Furthermore, the scaling up of such VUV photon source seems straightforward. For example, a 10 MW ion thruster for interplanetary mission with 10 kV (I_(sp)˜5,000 sec) acceleration would require a cluster ion beam of 1 kA with a ion flux of 6.3×10²¹ ions/sec. This would require at least 6.3×10²¹ VUV photons per second. With a photon energy of 10 eV, the required photon source power is 10 kW, which is well within reach of near-future VUV source technologies.

Another advantage of the present invention is that it does not use rare gas for ion transportation in addition to fullerene fuel. Therefore, the structure of the present invention can be considerably simpler and lighter than the exiting fullerene ion thrusters that use conventional discharge plasma technologies. Furthermore, the thrust efficiency of the present invention is significantly high because does not require mixing with rare gas, which reduces the overall thrust efficiency of fullerene-based ion thrusters. Qualitatively, the summary of the advantages of the present invention over the conventional exiting ionization method for fullerene ioni thrusters is presented in Table 1.

TABLE 1 Comparison of exiting ionization method and the present invention for fullerene ion thrusters. Existing Ionization Method Present Invention Ionization Physics Electron Impact Ionization or Photoionization Charge Exchange Internal Energy Much Higher than Lower than Deposition due to Fragmentation Threshold Fragmentation Ionization Threshold Gas Required In Yes No Addition to Fullerene Fuel Scaling Up Difficult Easy Structure Complicated Simple Thrust Efficiency Low High Fullerene Fuel Usage Very Low High Usage of Fullerene Not Possible Possible Derivatives Usage of Fullerene Not Possible Possible Nanotubes and Their Derivatives

Another important aspect of the present invention is in its ability of ionizing with minimal fragmentation of functionalized fullerenes, fullerene nanotubes, and fullerene nanotube derivatives, which have larger mass than fullerenes and can be tailored for mission specificities. Currently, chemists in the world have successfully produced bulk quantities of varieties of functionalized fullerenes (fullerene derivatives), such as C₆₀-F₄₈, which was recently shown to be evaporable without fragmentation. For example, C₆₀-F₄₈, has a mass of is 1632.

The thrust density of C₆₀-F₄₈ can be 5 times higher than that of C₆₀ alone, and 150 times higher than that of Xe. The potential usage of other heavier functionalized fullerene, fullerene derivatives, fullerene nanotubes, and fullerene nanotube derivatives can further increase the thruster density. Therefore, the successful usage of such fullerene derivatives in the present invention will result in more compact and lighter ion thrusters, thus can greatly expand the usage of ion thrusters for unprecedented space mission applications further beyond ion thrusters using fullerene ions. The ionization with minimal fragmentation of such large fullerene derivatives can be readily achieved by the present invention that uses VUV photoionization.

BRIEF DESCRIPTION OF THE DRAWINGS

Elements in the figures have not necessarily been drawn to scale in order to enhance their clarity and improve understanding of these various elements and embodiments of the invention. Furthermore, elements that are known to be common and well understood to those in the industry are not depicted in order to provide a clear view of the various embodiments of the invention.

FIG. 1 illustrates schematically a high thruster density ion thruster based on photoionization of fullerene, fullerene derivative, nanotubes, or nanotube derivatives clusters generated by an effusion source with an aperture showing the fundamental principle of the present invention.

FIG. 2 illustrates schematically a high thruster density ion thruster with plural apertures based on ion beams of the fullerene, fullerene derivative, nanotubes, or nanotube derivatives generated by an effusion source (or plural effusion sources) and single or plural VUV photon sources.

FIG. 3 illustrates schematically an example of a high thruster density ion thruster with plural slit apertures based on ion beams of the fullerene, fullerene derivative, nanotubes, or nanotube derivatives generated by an effusion source (or plural effusion sources) and single or plural VUV photon sources.

FIG. 4 illustrates schematically an example of a high thruster density ion thruster with plural annular apertures based on ion beams of the fullerene, fullerene derivative, nanotubes, or nanotube derivatives an effusion source (or plural effusion sources) and single or plural VUV photon sources.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In the following discussion that addresses a number of embodiments and applications of the present invention, reference is made to the accompanying drawings that form a part hereof, in which is shown by way of illustration specific embodiments in which the invention may be practiced. It is to be understood that other embodiments may be utilized and changes may be made without departing from the scope of the present invention.

The fundamental principle of the present invention lies in the usage of photoionization for ionizing fullerene-family clusters, including but not limited to fullerene clusters, fullerene derivatives, nanotubes, and nanotube derivatives, generated by a molecular beam source, including but not limited to various effusion sources, such as Knudsen cells. In the following descriptions, fullerene clusters can represent fullerene-family clusters or molecules without departing from the scope of the present invention.

FIG. 1 illustrates schematically a fundamental aspect of the present invention, which is a high thruster density ion thruster based on VUV photoionization of fullerene clusters, 102, generated in a thermal effusion source, 101. The thermal effusion source is a molecular beam source activated by thermal heating, energized by radiation, electrical or other means. Fullerene, 102, are evaporated from a bulk fullerene solid, 103, exiting an aperture, 105, forming a thermal fullerene molecular beam, 104, ionized by a VUV photon beam, 111, which is generated by a VUV photon source, 110. The VUV photon source, 110, includes, but limited to, resonance line sources and excimer sources that can be energized by energizing mechanisms, including but not limited to, electron beams, DC or RF discharge, or their combinations. The photoionized fullerene ions are accelerated first between the first electrode, 120, and the second electrode 121. In some cases, the first electrode can be the frontal surface of the thermal effusion source without departing from the scope of the present invention. The photon flux and the fullerene density are maintained such that the fullerene clusters are fully ionized with minimal multiple ionization and internal energy deposition. The photoionized fullerene ions are further accelerated by the third electrode, 122, to a full exit velocity. The fully accelerated fullerene ions form an ion beam, 140, which produces thrust.

The number of electrodes can be varied depending on applications and preferred thruster configuration. The voltages between electrodes can be varied depending on applications and preferred thruster configuration. The electrodes can be solid plates, apertures or grids, or their combinations, depending on applications and preferred thruster configuration. Other components that are not shown in FIG. 1 are electrostatic focusing and steering elements, and electron sources that neutralize the spacecraft. The number of these elements can vary depending on applications and preferred thruster configuration. Other units that are not shown in FIG. 1 are power sources, control units, and structural elements that attach the thruster to the space vehicle.

FIG. 2 illustrates schematically a high thruster density ion thruster based on photoionization of fullerene clusters, 202, generated in a thermal effusion source, 201. Fullerene clusters, 202, are evaporated from a bulk fullerene solid, 203, exiting plural apertures, 205, forming a thermal fullerene beam, 204, ionized by a VUV photon beam, 211, which is generated by plural VUV photon sources, 210. The thermal effusion source is a molecular beam source activated by thermal heating, energized by radiation, electrical or other means. The VUV photon sources, 210, include, but limited to, resonance line sources and excimer sources that can be energized by energized by energizing mechanisms, including but not limited to, electron beams or DC or RF discharge. The photoionized fullerene ions are accelerated first between the first electrode, 220, and the second electrode 221. In some cases, the first electrode can be the frontal surface of the thermal effusion source without departing from the scope of the present invention. The photon flux and the fullerene density are maintained such that the fullerene clusters are fully ionized. The photoionized fullerene ions are further accelerated by the third electrode, 222, to a full exit velocity. The fully accelerated fullerene ions form ion beams, 240, which produce thrust.

The number of thermal effusion sources can be greater than one without departing from the scope of the present invention. The number of electrodes can be varied depending on applications and preferred thruster configuration. The voltages between electrodes can be varied depending on applications and preferred thruster configuration. The electrodes can be solid plates, apertures or grids, or their combinations, depending on applications and preferred thruster configuration. Other components that are not shown in FIG. 2 are electrostatic focusing and steering elements, and electron sources that neutralize the spacecraft. The number of these elements can be depending on applications and preferred thruster configuration. Other units that are not shown in FIG. 2 are power sources, control units, and structural elements that attach the thruster to the space vehicle.

FIG. 3 illustrates schematically a multiplexed example of the present invention, a high thruster density ion thruster based on photoionization of fullerene clusters generated in a thermal effusion source, 301. Fullerene are evaporated from a bulk fullerene solid exiting plural slit apertures, 305, forming a thermal fullerene beam, 304, ionized by VUV photon beams, 311, which are generated by plural VUV photon sources, 310. The VUV photon sources, 310, include, but limited to, resonance line sources and excimer sources that can be energized by energized by energizing mechanisms, including but not limited to, electron beams or DC or RF discharge. The photoionized fullerene ions are accelerated first between the first electrode, 320, and the second electrode 321. In some cases, the first electrode can be the frontal surface of the thermal effusion source without departing from the scope of the present invention. The photon flux and the fullerene density are maintained such that the fullerene clusters are fully ionized. The photoionized fullerene ions are further accelerated by the third electrode, 322, to a full exit velocity. The fully accelerated fullerene ions form ion beams, 340, which produce thrust.

The number of thermal effusion sources can be greater than one without departing from the scope of the present invention. The number of electrodes can vary depending on applications and preferred thruster configuration. The voltages between electrodes can vary depending on applications and preferred thruster configuration. The electrodes can be solid plates, apertures or grids, or their combinations, depending on applications and preferred thruster configuration. The VUV sources can be of a point, planar, slit, annular or combination source configuration. Other components that are not shown in FIG. 3 are electrostatic focusing and steering elements, and electron sources that neutralize the spacecraft. The number of these elements can vary depending on applications and preferred thruster configuration. Other units that are not shown in FIG. 3 are power sources, control units, and structural elements that attach the thruster to the space vehicle.

FIG. 4 illustrates schematically a multiplexed example of the present invention, a high thruster density ion thruster based on photoionization of fullerene clusters generated in a thermal effusion source, 401. Fullerene are evaporated from a bulk fullerene solid exiting plural annular apertures, 405, forming a thermal annular fullerene beam, 404, ionized by VUV photon beams, 411, which are generated by plural VUV photon sources, 410. The VUV photon sources, 410, include, but limited to, resonance line sources and excimer sources that can be energized by energized by energizing mechanisms, including but not limited to, electron beams or DC or RF discharge. The photoionized fullerene ions are accelerated first between the first electrode, 420, and the second electrode 421. In some cases, the first electrode can be the frontal surface of the thermal effusion source without departing from the scope of the present invention. The photon flux and the fullerene density are maintained such that the fullerene clusters are fully ionized. The photoionized fullerene ions are further accelerated by the third electrode, 422, to a full exit velocity. The fully accelerated fullerene ions form ion beams, 440, which produce thrust.

The number of thermal effusion sources can be greater than one without departing from the scope of the present invention. The number of apertures on the thermal effusion source can vary depending on applications and preferred thruster configuration. The number of VUV photon sources can vary depending on applications and preferred thruster configuration. In some situations, the VUV sources can be arranged in a circular fashion with the VUV photon beams directed to the center of the fullerene cluster beams. The number of electrodes can be varied depending on applications and preferred thruster configuration. The voltages between electrodes can be varied depending on applications and preferred thruster configuration. The electrodes can be solid plates, apertures or grids, or their combinations, depending on applications and preferred thruster configuration. The VUV sources can be of point, planar, slit or annular source configuration. Other components that are not shown in FIG. 4 are electrostatic focusing and steering elements, and electron sources that neutralize the spacecraft. The number of these elements can be depending on applications and preferred thruster configuration. Other units that are not shown in FIG. 4 are power sources, control units, and structural elements that attach the thruster to the space vehicle. In some cases, plural ion thrusters can be used in a single space vehicle.

More specifically, the fullerene clusters used in the present invention can be replaced with fullerene derivatives or functionalized fullerenes, including but not limited to fluorinated, hydrogenated, hydroxylated, chlorinated, and brominated fullerenes without departing from the scope of the present invention. The examples of fluorinated fullerene derivatives include but not limited to C₆₀F₃₆, C₆₀F₄₈, and C₆₀F₆₀. The examples of hydroxylated fullerene derivatives include but not limited to C₆₀(OH)_(n) with n can be 1-60. The examples of hydrogenated fullerene derivatives include but not limited to C₆₀H_(n) with n can be 1-60. The examples of chlorinated fullerene derivatives include but not limited to C₆₀Cl_(n) with n can be 1-60. The fullerene derivatives may have attachment of other organic and inorganic molecules without departing from the scope of the present invention.

The fullerene clusters used in the present invention can be replaced with fullerene nanotubes or their functionalized forms, including but not limited to fluorinated, hydrogenated, hydroxylated, chlorinated, and brominated fullerene nanotubes without departing from the scope of the present invention. The fullerene nanotube derivatives may have attachment of other organic and inorganic molecules without departing from the scope of the present invention. 

1. A system of photoionization of fullerene and derivative clusters for ion thrusters, said system comprising: (a) VUV photon sources suitable for ionizing fullerene and derivative clusters; (b) means of blocking and clearing deposition of fullerene and derivative clusters on the window of photon sources; (c) means of generating vapors of fullerene and derivative clusters; (d) means of accelerating the ionized fullerene and derivative clusters.
 2. The photoionization system claimed in claim 1 further comprising the high flux VUV photon sources including, but not limited to, rare gas resonance lamps, such as and rare gas line or excimer lamps.
 3. The photoionization system claimed in claim 2 further comprising the VUV photon generation system comprising: (a) an energizing system, optically or electrically, which excites or ionize rare gas elements; (b) a VUV transparent window; (c) a discharge chamber containing rare gases with or without other types of gases; (d) a baffle system that blocks deposition of fullerene and derivative clusters on the window; (e) a heating system that evaporates, thus clears the deposition of fullerene and derivative clusters on the window;
 4. The photoionization system claimed in claim 1 further comprising the ion extraction and focusing system comprising: (a) electrostatic lens and extraction elements; (b) electrostatic focusing system; (c) heating elements to evaporate the deposited fullerene and derivative clusters on electrodes and extraction system.
 5. A method of photoionization of fullerene and derivative clusters for ion thrusters, said method comprising: (a) VUV photoionization step of fullerene and derivative clusters; (b) steps of blocking and clearing deposition of fullerene and derivative clusters on the window of photon sources; (c) steps of generating vapors of fullerene and derivative clusters; (d) steps of accelerating the ionized fullerene and derivative clusters.
 6. The photoionization method claimed in claim 1 further comprising the high flux VUV photoionization step including, but not limited to, the usage of rare gas resonance lamps, such as and rare gas line or excimer lamps.
 7. The photoionization method claimed in claim 2 further comprising the VUV photon generation method comprising: (a) an energizing step, optically or electrically, which excites or ionize rare gas elements; (b) the use of a VUV transparent window; (c) the use of a discharge chamber containing rare gases with or without other types of gases; (d) a baffling step that blocks deposition of fullerene and derivative clusters on the window; (e) a heating step that evaporates, thus clears the deposition of fullerene and derivative clusters on the window;
 8. The photoionization method claimed in claim 1 further comprising the ion extraction and focusing method comprising: (a) the use of electrostatic lens and extraction elements; (b) the use of electrostatic focusing elements; (c) a heating step to evaporate the deposited fullerene and derivative clusters on electrodes and extraction elements. 